Flying-machine.



H. E. HAWES. FLYING MACHINE. APPLICATION FILED sEP Q, 1909.

6 SHEETBBHEET 1.

I V/TNESSES: INVENTOR.

Patented July '15, 1913.

H. E. HAWES.

FLYING MACHINE. APPLICATION FILED SEPT. 11, 1909.

e SHEETS-SHEET 2.

H. E. HAWES. FLYING MACHINE. APPLICATION FILED SEPT. 9, 1909.

1,067,425, Patented July 15, 1913.

.36, 6 SHEET8-SHEET 3.

32 WI T N ESSES:

H. E. HAWES. FLYING MACHINE. APPLIOATION FILED SEPT. 9, 1909.

Patented July 15, 1913.

6 SHEETS-BHEET 4.

H. E. HAWES. FLYING MACHINE. APPLICATION FILED SEPT. 9, 1999.

A I 7 4a 40,11 Z L"! N K v /7 0 f BEE H 5 Q 5 WITNESSES- Patented July 15, 1913. v

6 SHEETS-BHEET 5.

Patented July 15, 1913.

6 SHEETSSHBET 6.

WI T 1V5 SS5 5.-

UNITED STATES PATENT OFFICE.

HERBERT E; HAWES, OF NEW YORK, N. Y.

FLYING-MACHINE.

Specification of Letters Patent. Pat t d July 15, 1913,,

Application fil ed September 9, 1909. Serial No. 516,968.

proved form of supporting surfaces, em-

bodyin the desired features of simpllcity and efi'iciency.

A further object of my invention is to provide an automatic balancing device for the machine.

A further object of myinvention is to provide a brake or check adapted to arrest the forward movement of the machine at desired times.

Further my improved machine embodies an improved method of staying or bracing the main frame, and means for enabling the machine to be used either on land or water.

My invention consists in the construction, combination andarrangement of parts set forth in and falling within the scope of the appended claims. In the present instance I have omitted showing the motor accessories, as the art therein is too well known to need description, and furthermore any suitable motor may be used of the requisite weight and power. The propellers shown herein, also, the landing mechanism, and gyroscope mechanism, being -matter under a different class, will be made subjects of applications separate herefrom.

In the accompanying drawings like reference characters indicate like parts in the various views, the drawings not being made to scale, certain parts are exaggerated in size for clearness in illustration.-

Where there are identical parts in the opposite sides of the machine I have detailed only one side, the propellers for example in Figures 2 and 3.

In the drawings :Fig. 1 is a general side elevation of my machine. Fig. 2 is a plan view, with the supporting planes removed and in which I have detailed only one side, where there are two similar parts on opposite. sides, and shown the gyroscope rim in outline, omitting the spokes; Fig. 3, is a unit-s, I use a hoop or band F front elevation with the same side detailed as Fig. 2; Figs. 4-5 show side and end elevation of'propellers; Fig. 6 shows side and end elevation of lever locking device; Fig. 7 shows end elevation of propeller sleeve bearings; Fig. 8 shows side elevation of gyroscope shaft; Fig. 9 is a plan view of same, and friction clutch; Fig. 10 is a horizontal section through center of the gyroscope universal joint; Fig. 11 shows propeller actuating mechanism, and friction clutch details; Fig. 12' shows details of plane supporting wheels, and mechanism for dropping rear of frame; Fig. 13 is a side elevation, partly in section and partly broken away, showing details of gyroscope sleeve, rim, brake arms, brake actuating mechanism, universal joint, and sleeve look-'- ing nut. Fig. 14 showsside elevations of propeller sleeve bearin s, partly in section; Fig. 15 is a view of yielding guy-wire, fasten; ings, or anchorage; Fig. 16 is a plot of the movement of planes B-B and the cooperating parts and connections; Figs. 17-48-19 are views of the pontoons in combination with the wheel frames for marine work. I

For clearness in illustration, I have shown the check planes in their normal or inoperative positions in Fig. 1. In Fig. 2, they are shown in the operative position, or cross-- wise of line of motion.

D represents the operators seats, M the.

motor. I

In carrying my invention into practice, I construct a frame'of strips F of wood or of any desired material having the necessary strength and lightness, foil A, on minor secondary frames, of curved cross section, these in turn, I fasten to top of frame F, as shown in Figs. 123. These supporting surfaces I prefer to make in separate parts, in this instance four, although I might make them the entire length of the main frame, and use one or two sections only, the number being optional. By

making them somewhat larger in front and with de ressed sides, the air entering them, on the orward movement of the machine, is forced toward the center, and consequently forces the contained air downward; and, reacting in the opposite direction, produces an increased, lifting efiect on the supporting surfaces, more so than if it were acting on planes with straight or undepressed sides or edges. In constructing these supporting at the large and fasten the aeroof the same shape as shown in Fig. 2.

strips, of wood preferably,

and-small end thereof, to give them the desired shape and fasten the aerofoil which may be of any suitable material, to the inside, so as to offer a smooth surface to air resistance.

In Fig. 2 only the rear plane is shown in outline, the three forward planes being shown in elevation in Fig. 1, and the are long the sides of these minor frames, I afix light f to fasten the aerofoil to, and in turn fasten these to the top of frame F, although, in many cases,thev

aerofoil might be fastened to the frame F direct, without departing from my invention. To help preserve the curved crosssection shape, I also mount between the end frames smaller and lighter reinforcing strips f, which maybe placed either in the same direction as strips F as shown, and fastened to the side strips f, or lengthwise of planes, and fastened to members F. In practice, I prefer to mount strips f longitudinally of machine, and fasten same to strips F. In either case, the supporting surface fabric or aerofoil A .is fastened to the inside.

It will be understood that it is optional to use ,a single supporting surface, of my improved shape, extending the full length of the machine, or a plurality of smaller sized planes, with the same aggregate amount of supporting surfaces. These planes might be made also,'without the narrowed or contracted rear end, using the depressed sides, without departing from my invention.

For propelling themachine forward, I use two propellers rotating in opposite directions, disconnectible from the motor by a friction clutch, and located preferably, on

opposite sides of the frame, behind the wings of same, see Fig. 2; These propellers'are mounted on the ends of shafts c, which revolve in bearings in movable sleeves c pivoted at 0", transversely of the machine, for the purpose of giving the propellers an upward inclination, to exert alifting, as well as propelling action at certain times, as in rising from the ground. Their shafts a are inclined or adjusted by movement of the hand lever a, which -is disposed and proportioned, so as to give them. any desired inclination deemed desirable, lever a being pivoted to the frame F at one end as shown in Figs. 2 and 12. In this instance, only a few degrees of elevation are provided for by proportions and throw of lever at; although said lever might be made to give the propellers a nearly or quiteperpendicular lifting action, by increasing its scope of action. This description applies to both propellers, although it might be used in case of only one propeller, placed in the center of machine.

- propeller.

From sleeve C rod '0, pivoted thereto at its free end, and to rock lever 56 on shaft 56, which extends crosswise of the machine, and has rigidly fastened to its oppositeend a similar lever connected with the movable shaft bearing 0 on opposite side of machine, for giving synchronous elevating movement to the opposite Said slmilar lever-being a duplicate, 1s notshown in the drawings'on opposite side.

By throwing over lever a, from its normal or rear position, as shown in Fig. 1', to its extreme or forward position, shown in Fig. 12, shaft 56 is rocked, causing simultaneous upward inclination of propeller shafts 0, tions 0. I

The blades U of the propellers extend in a helix about the central shaft 0. To enable the use of blades of very light material, I erect on-shaft c radial armsd, on lines corresponding to the helical pitch of the propellers, and fasten blades U to their outer ends, arms d serving as ribs to preserve their shape. This construction enables me to use very thin sheet metal, or even fabric, without the tendency of the blades to buckle or warp out of shape, as the radial arms, ex tending across blades U, stay them and tend to keep them in shape while in action. I prefer to use only the outer portion of arms d, for support of blades U, 'making said blades relatively longer and narrower, thereby preserving the same amount of surface. If they extend to the center or to shaft 0, the inner portion assumes a more obtuse angle to the plane of rotation, and offers more resistance, and is not presented at a favorable angle. for propulsion. To brace arms (i, I stay them by wires or guys 6, running over circular rims E, mounted concentrically on shaft 0, held and braced by spokes 6 like a bicycle wheel rim said arms resting in central radial apertures formed in rims E. The spokes are provided with threaded ends and nipples for adjustment in the well known manner. These guys extend in opposite directions and rearwardly from blade U, over rims E, and fasten rigidly to the outer end of an opposite arm (1, being rigidly fastened also to rim E where they rest on its circumference, .in any suitable manner, and are provided with means for adjusting their tension in any suitable way. Forturning these propellers I connect them with the motor in the following manner: On shaft 0 I rigidly mount helicalv gear 1:, and, on' transverse shaft IV running in bearings W extending from sleeve 0, a mate gear 4). On the motor shaft, I mount slidably,a member X forming one part of a friction clutch, the other member, gear X, being revolubly mounted on same. Member X contains a circular groove in whichacts yoke lever K,

extends downwardl a pivotally mounted on a support K. From opposite end of yoke-lever K, a connection L leads to lever .1', pressure on which, separates members X-X stopping the propellers. While running, the friction clutch members are held together by spiral spring L. In bearings N extending from the motor base, are mopnted short transverse shafts N, on which are mounted helical gears X, connecting with the propellers through inclined transverse shafts W; these are provided with universal and slip joints between gears X"-v, to prevent binding same, by twisting of frame. The teeth of the helical gears X-X-o-v are so cut and arranged that the shafts 0 are rotated in 0pposite directions. These propellers may be driven by belts, flexible shafts, or chains if preferred, and any form of clutch 0r mechanism between them and the motor may be used, so that they are started gradually and uniformly. One propeller only is shown in Figs. 1 and 2. It will be understood that a duplicate propeller is used on the opposite side. The blades U are preferably made of thin metal, and are fastened to arms (1 by rivets, clamps, or any suitable way- Members c, d, e and the other cooperativeparts, are preferably of steel, 0 of aluminum.

To automatically, balance my machine against sidewise roll or tip, I employ two automatically moved balancing planes,

B-B mounted on transverse horizontal shafts s pivoted to the machine frame, at the extreme right and left of the frame wings, see Figs. 2-3. For moving these planes automatically, I employ the tipping motion of the machine itself, using as a fulcrum or working point, the shaft S of a well known, although not extensively used device, called a gyroscope; whose peculiar property or function, of always maintaining its original plane of rotation irrespective' of the movement of its support, I make use of as follows: The gyroscope consists of a relatively heavy metal rim Y, of large diameter, mounted on a vertical sleeve S, provided with a universal joint or bearing, said rim being hung below the machine frame centrally, and under the main supporting surface. Said rim is held to shaft S and sleeve S, by staggered offset spokes Y, like a bicycle wheel rim, engaging flanges T onsleeve S. The spokes are provided with threaded nipples to adjust the tension thereof in the well known manner. Shaft S extends from ball Q, downward through sleeve S, being provided with i a threaded end and nut S, by which ball Q, shaft S, and sleeve S, are locked together.

partly in section, to illustrate more clearly its construction-through line A-A Fig. 9-see Fig. 13. The body is composed of two parts 39-39, member 39 having ex tension lugs 40-40', for the motor shaft bearings. The shaft ball Q, is composed of three sections 41-41-41" which are provided with taper seats and held together as one, by shaft S, which is made in two sections, one a sleeve S, which is the gyroscope wheel hub, and the other extending from the top of frame 0, downward through ball Q, and hub of gyroscope and tightened with a nut S below. The part of shaft S above Q, is enlarged and cone-shouldered where it engages the upper side 41 of ball Q; the smaller part extending through Q and said sleeve S, and threaded at itslower end to receive nut S whereby the three sections of ball- Q are clamped and held together.

The central section 41 of ball Q is ring shaped, and provided with a conical seat on each side, for the reception of the sections 41-41". It is further provided with two diametrically opposite V shaped slots 4747-47 not shown-in its periphery, for the reception of the driving rollers 42-42. Surrounding ring 41 is the annular helical gear 43 running on ball bearings, in races 45-45 in the body 39-39, and corresponding races 44-44 formed in its upper and lower sides. 'On the interior of gear 43 are formed two studs 46-46, 46 not shown, carrying conical rollers 42-42, 42 not shown, which engage in corresponding V-shaped slots 47-47, 47 not shown, in ball member 41, said studs being disposed diametrically opposite each other, and in the same plane with center of ball Q, which is free to swing in any direction, within the limit of the clearance spaces provided in slots-47-47, 47 not shown,-and the openlngs in body 39-39 at top and bottom of same, provided for shaft S. The body is composed of two cup shaped. members 39-39 spaced apart by legs 49-50-51-52, for the reception of gear 43, and provided with ball races, 45-45, the balls in which'bear on members 41-41. The body members are held together by screws through the legs, the complete fixture being bolted to frame F, through flanges 54-55 1 on opposite sides thereof. Meshing with gear 43 is helical gear H, on motor shaft I, running in bearings 40-40 extending from joint body-member 39.

It will be understood that the gyroscope wheel Y might be mounted in other positions relative to the frame of the machine, and on other than universal bearings; alsothat it might be held from swaying without stopping its rotation, and that it might be disconnected from its actuating power source at other places than the motor shaft I; as, for instance, it might be provided with a friction device in its hub, and disconnected thereat, or it might be provided with a friction device at ball Q for disconnection and control. To allow for longi- 'tudinal or pitching movements of the ma-' chine, without binding shaft S, I form ing frame 0. Frame frame 0 with a slot 0 to allow free-movement of shaft S fore and aft, without mov- O is pivoted longitudinally of frame, on cars 57-57, projecting upwardly from body 39, see Figs. 8-9. Shaft S is provided with a slide or wearing block where it works in slot 0' in frame 0.

To impart rotary motion to rim Y of the gyroscope wheel, said rim being held and connected to shaft S by wire spokes Y like a bicycle wheel rim, I employ gear H, see Fig. 9, which also serves as the female member of a friction clutch; the male member H being slidably mounted and feathered on shaft I, and normally held into engagement with H by spring K; disconnection being made by pressure on foot treadle L, through connecting wire L and yoke N", acting in groove N in sleeve H to, separate the clutch members.

To vavoid undue swing of the gyroscope wheel, and to stop said wheel more quickly, I provide a friction brake consisting of four pivoted arms Y to engage the outside of rim Y; said arms being pivoted horizontally at their upper ends on hearings on the machine frame, their lower or free ends being movable, radially, relatively to rim Y. This friction device also serves the double purpose of initially holding the gyroscope in proper relation to the machine for starting same, and to'prevent it from swaying dangerously in landing, which might derange its driving mechanism,.or cause damage to adjacent parts of the machine. These friction arms are actuated from lever K by connections J leading to a central ring G, inclosing shaft S, and held in position on a bearing G fastened to the machine frame.

By reason of tangential connections, a circular movement of ring G, causes a pull upon wires.J and a simultaneous inward movement of arms Y causing them to fric-. tionally engage the outside rim Y, thereby stopping same; and by continued'pressure upon lever K,-to retain ring Y against sidewise displacement, until release of pressure of arms Y by return of lever 'K to its original position; the friction arms being heldnormally away from ring Y by spiral springs Z. Bearing G is provided with a circular shouldered seat, for reception of actuating ring G, see Fig. 13, and is located concentric with shaft S, and held to frame of machine by posts M. Actuating ring G s given its circular arm tightening motion or movable end per arm G of rocklever Gr', through the lnner arm it and connection h, connected to the rear of pivoted balancing plane B, giving it its upward inclination, by reason of the lengthened distance obtaining through the frame oscillating to the son of shaft S'remaimng in its original or normally upright position, owing to the peculiar property or function of the gyroscope wheel Y maintaining its horizontal plane of rotation, causing frame 0 to oscillate on its pivots, thereby causing a pull on tension connection 6 fastened to its upper to positively incline left hand plane B. 1 i From the lower arm 2' of left hand rocklever G, extends a connection '0, to the lower right machine, by which a negative inclination is given the right hand plane B, which tends to depress the right of the machine simul taneously; said motions. A'tipping motion to the right causes a reverse movement of the respective parts, and a positive inclination of right hand plane B, and negative left.

The gyroscope may be actuated by belts or chains, instead of gears, if so desired, or any other way at option. The gyroscope rim is'made of metal, preferably, as are the other parts of same. The ball Q, and its cooperating parts, are of steel preferably, and hardened.

For balancing my plane laterally, while the gyroscope is thrown out of action, Iuse two hand actuated auxiliary planes B'' located at the extreme right and left of the machine; said planes being mounted on transversely pivoted horizontal shafts 60, and actuated from hand wheel 61 on steermg post 62 through connections 59, so connected, that a'movement of the rear of said right, by rea.

hand arm 2, on opposite side of see Fig. 16 which gives a plot of v wheel Glto the'left gives an upward inclination of the left hand plane B, and a simultaneous downward -inclination of the right hand plane; an opposite movement of wheel 6 l producing opposite results. The connectlng wires 59, are led from arm 63 on post 62, to rocklevers 64; which serve only to change-the direction of motion, in the connections, from post 62 to planes B B. I

The rocklevers 6 Lit will be observed-are provided with an arm above and below their pivots; the lower .one'being connected to the arm 65 on rear of post 62, by connections 65, insures a-simultaneous opposite motion to the .respective planes, on movement of wheel 61 in either direction.

It will be observed that a method of depressingthe rear of the machine hereinafter described will be very advantageous in case of marine work when rising from the water,

as pontoons may be used'in place of wheels, or in combination therewith, the wheels pro-- suitable light material.

jecting below the boats, so as to make the machine available for both land and water without change. For such use I have shown a method of combining the pontoons with the wheels, see Figs. 17 18, 19, which show an end, side, and plan view of the parts of the frame of the machine, suitably arranged for such combination, which is as follows: I provide the pontoons 7l72 'with central vertical openings 70, entending from top to bottom, and made water tight, of sufficient size to allow for free passage oflwheels 32 mounted on hinged frames 66. From each side of the forward frame 66 extend arms 6768 engaging in sockets 69-69 built in each side of the opening 70, in the bow. To allow for change or variation in distance when either front or rear wheel 32 is depressed independently by reason of its striking the ground or water first, I provide, in rear opening 70 and on each side thereof, levers 71 7 2', hinged at their lower ends to inside of said opening, their movable upper ends, engaging and pivoted to arms 6768 on frame 66. Frames 66 are free to swing, longitudinally in said rear opening 70, and

'to allow for independent depression of either bow or rear wheel 32, without undue strain, either upon frame of machine, or upon the pontoons. Of course, it is understood that these pontoons are water. tight, and that these openings are boarded up from deck to bottom and that the sockets 69-69 and arms 67-68 are so proportioned and located that wheels 32 project below pontoons a sufiicient distance to allow landing on said wheels without striking the pontoo-ns on the ground. Thus it will'be seen that the machine may land on either land or water, as, when landing on solid foundation, the wheels .are pressed upwardly carrying the pontoons up with them, and keeping them from the ground and out of danger of damage or strain from collision with same.

The pontoons are made of wood, or any In alighting, and at other times, it may be desirable to arrest, or check the forward movement of the machine more quickly than it would normally come to rest by merely stopping the propellers. To more quickly .and certainly. effect such stoppage, I have provided vertical check planes 8 and 9, normally held out of action, in planes longitudinal with the forward movement of the machine, see Fig. 2, planes 8 and 9, being mounted on vertical pivot shafts 8'-and 9', and adapted to be swung crosswise of the machine and present a large retarding surface. These planes are swung into action by movement of lever 10 through connect-- ing wires 10 and 10?. On release of lever 10, the planes 8-and 9 resume their normal positions, by reason of the. preponderance of air pressure on their rear portwns, al-

' though they might be positively returned by spring, or otherwise. Connecting wires 10 and 10 engage levers 11 and 11,

rigidly fastened to vertical pivot shafts 8' and 9', and are led forward to two levers 19,

on the sleeve 19, loosely mounted on shaft 56', also provided with a third lever 20,

which connects through wire 20 ,with lever 10. Lever 10 is provided with the leverlocking device shown in Fig. 6. a

Of course it would be possible to arrange a check plane in other positions, and operate itby other means than described; for

instance, planes 8 and 9 might be rolled on a roller like a window shade, and placed crosswise of line of movement of machine,

and unrolled to present check surface. It-

will be understood tha-tthese check planes may be wholly or partially operated or swung crosswise, within the limit of movement of lever 10, as may be desired or necessary.

For steering the machine to either side,

which are employ vertical rudder planes 12, pivoted,

on a vertical 'shaft 13 provided with double end lever 25, to the rear of frame F. These planes are moved by arms 13' and 13 on steering post 14: provided with hand wheel 14', through connections 15 and 15, and are spaced apart and stayed together, so as to move synchronously as one. Pulleys It have no function other than to change the direction of connecting wires 15-15 to bring them past the motor without interfering with same.

To steerthe machine to thdright, movement is given so that the rear of the'hand wheel revolves to theright. Movement to the left produces,the opposite effect. To govern the rise and fall of the machine, I employ horizontal double rudder planes 16, pivotally mounted on horizontal transverse shaft 16 held in a frame work extending in front of the machine. These planes are spaced apart and held by trusses orstays T. For turning or changing their angle, I provide a band wheel 16 rigidly fastened to shaft 16' over and to which passes and is fastened bands or wires 17 and 17 connecting with actuating lever 18" on opposite sides of its axis 18', so that movement either way of lever 18" will cause a movement of the planes 16 about their axis 16'; wire 17 is fastened to wheel rim 16" at the forward part on which the wire is always in contact, as at 16". In Fig. 1, lever 18, being mounted on the same axial line as lever 37, is not ends of which extend upwardly, portion! or groove 22, from the movement, I em l 45 movement by lever-1'8 the uniting to form bearing for shaft 18', and provided with bolt 'holes for fastening to frame F of machine, see Fig. 6. Twin levers 18 and18 are mounted on pivot 18; the 5 lower'end of one of which 18 is provided on its side, with a shoe 23 which extends into, and slides in groove 22, and has a double incline, or raised part 23 on which operate two flanged rollers 24 and 24, normally held toward each other and into looking engagement with the lower sides of slideway 22, and incline 23. These rollers are normally held toward each other by plungers 30-30, which are pressed toward 5 rollers 24 and 24", by spiral springs 29 and 29, said'plungers and springs operating in recesses formed in opposite ends ofshoe 23. To release these rollers, so as to allow movement of shoe 23 on the-secondary, section of lever 18", connecting with wires 17417, I

form the primary member, lever 18, with a trip point 27 passing through an opening 31 in the lower end of secondary lever 18", into slideway 22, and between rollers 24 25 and 24'. To guide the machine upwardly, r by giving planes 16 an upward inclination, the handle or upper portion of lever 18 is pulled toward the rear, point 27 forcing roller 24 down the incline of shoe 23, which 30 moves the plunger 30 and compresses the thereby unlocking shoe plunger spring 29,

'23, which is moved toward the front of the machine, by reason of point .27 engaging the wall of the aperture 31 in lever 18", of 35-which shoe 23 is an integral part. The roller 24, in the opposite end of shoe 23,

is automatically unlocked by reason of the increased space into which it is moved, by the releasing movement of its inclined seat in shoe'23. By this movement of the parts, the upper arm of lever18" causes a pull on connection 17, which gives inclination of planes 16,- which tends to raise the bow of machine. On cessation of plunger springs 29 and 29 instantly force plungers 30 and 30, against rollers 24 and 24 causing them to lock between incline. 23 and lower wall 1 of slideway 22, and hold lever 18 iInmov-- able, until further movement of point 27 on lever 18. To guide the machine in the opposite direction, an opposite movement of lever 18 is r uired, and an opposite action of the relative parts takes place.

The leverlocking device may be used in connection with any. plane or mechanism that requiresto be moved by increments in either direction and automatically locked, as, for instance, the planes in a diriglble balloon. -The leverlocking device may also I "be placed with. its .frame Umrosswise of machine, and operated by a hand wheel in place of lever 181 I v .To-facilitate starting the machine from v the ground, I- drop, therear of the frame,

greater llfting angle.

an upward thereby giving the supporting planes a Raising the front would produce the same result, but would require a greater outlay of force, so I prefer to shorten the distance between the rear supporting surface or member and frame, momentarily while starting, afterward returning same to their original normal positions. The instrumentalities for doing this are as follows: The rear supporting wheels 32, are mounted in a movable fork or frame 66, hinged at 33, and a link from said frame extends upward and forms part of a toggle joint 34. To the upper toggle lever 35, is connected a wire 36 leading to lever 37. 0 hen the machine has cleared sufliciently from the ground, the lever 37 is released,

and the toggle joint resumes itsnorinal position, by reason of the weight of said frames and wheels. The wheels on each side are 5 connected so as to move simultaneously, through their connections, with lever 37.. To prevent straining the frame unduly on landing, I provide spiral springs 73, to cushion the upward movement of frame 66, inclosing a guide rod 74 pivoted to frame 66 at its lower end, and sliding in a passage in block 74', pivoted to the wheel frame and above the wheels as shown in Fig. 12. In the rear landing member the spring 73 incloses guide rod 74, which as shorter than member 74 in the forward landing member, and is best shown in Fig. 19; and slides in an' aperture in'pivot 34. Said spring abuts against lower side of pivot-.34 and operates with a shorter compression range than the buffer spring in the forward frame,

and in a similar manner. In some cases one rear wheel only may be movable, or provided with thetoggle joint for depress-"' ing the rear, and used in the centerof the frame. It is optional whether the toggle, joint is moved past its center line so as to lock, or be moved so as to nearly lock and so held in any suitable way. The same joint may also be moved positively both ways.

The pontoons may be made withan upwardly rounded bow and stern, to clear the ground more surel instead of the straight bottom shown in the drawings; and sleds 11 or runners may beused in place of wheels as shown, or any suitable ground landing device may be-used. v

The pontoonsare omitted in Figs. 1 and 2, but are shown in Fig. .3. Also the gyro scope wheel is shown in larger diameter in Figs. 1 and 2, and in smaller size in Fig. 3, so as to swing between the pontoons and clear same. The rock shaft 56 is also shown broken off in Fig. 3 for clearness in illus- 12 tration. 1

To ease the strain on brace 0r guy wires, in alighting and at other times when strained unusually, I prevent breaking same,

by mounting them on a flexible seat 78,1

which I afiix to the frame of machine. I provide the guy 76 with an enlargement or head 77 at its end, and under such enlargement, I interpose a yielding cushion, spring, or washer 77. This yielding cushion may be of circular form, or it may be formed with a slot or cut in 1ts side, to allow of slipping sidewise into place over the guy, as

may also the seat 78, to allow of slippingthe guy in sidewise, instead of through a hole in same. It' is immaterial which way it is. made, although positive retaining means must be used to keep guy in slot, if so made. The guy may be threaded at its end, and provided with a nut, or it may be bent at a right angle, or have its head upset thereon. The seat is attached to the frame in any suitable manner, and is made with a hole or slot, as may be desired, with a seat for the head and washer as shown in Fig. 15. These yielding guys may be modified, by fastening each end rigidly and providing a sidewise yielding fastening between the ends of 76, tosupport any parts of machine needing suchsupport, without departing from my invention; or the seat 7 may be yieldingly held to frame and the spring washer dispensed with. One end of guy may be threaded and provided with a] nut, to act as a turnbuckle to tighten the guy, and a head upset on the opposite end.

It will be understood that the automatic balancing device could be readily arranged to balance the machine longitudinally as well as laterally, but I prefer to manually balance the machine longitudinally, as the longer dimension of the machine being disposed in that direction, renders it less needful. It'can be done without departing from my invention, as all that would be necessary to longitudinally balance the plane would be to provide a transverse pivot to frame 0 and connect same to planes 16 by connection 1717, one above and one below the universal joint of gyroscope shaft. This would 7 allow frame 0 motion longitudinally and laterally. Of course, to cause frame 0 to I make such lengthwise movement, slot 0 would be unnecessary, and a frame without said slot, and .only a snug passage for shaft S would be required, provided with a down: ward extension to actuate wire 17 which might connect with a loosely mounted col lar on sleeve S.

I do not claim as my invention the front and rear rudders, as I am aware they have been used before, nor the method of turning same. In place of. the pulley on front horizontal rudder shaft, arms may be used, gears.- Neither do I claim broadly the gyroscope as a balancing means, but as an auxiliary for turning the balancing planes.

- To operate or fly mymachine, I-proceedasfollows :-The' motor being started, I first joint 34, allowing erned by said toggle joint; the front rudder started gained their normal speed, forward motion tion clutches are disconnected.

ing 1 through suitable connections, operates to inchne said planes; said connectlons compristhe frame, by a forward 37 which releases toggle the rear to drop as govdrop the rear of movement of lever planes 16 are set horizontally by lever 18, the propeller inclining lever a, is turned to its elevating position, as shown in Fig. 12; pressure is made on foot lever I, and gradually the frictional members XX' are let into contact, whereby the propellers are in rotation. When they have will have been imparted to the machine,

' which will now move forward on its wheels,

if on land, or its pontoons' if on water. When it is judged sufiicient headway has been acquired to rise, planes 16 are given an upward inclination to cause the machine to rise completely from its supporting element; then the gyroscope may be started, by release of foot treadle K, which releases the gyroscopebrake. Lever L is next released which sets the friction clutch HH into action, thereby putting the gyroscope in rotation for automatically balancing the machine. Foot lever K also levers I and L", are provided with the well known retaining catches for keeping them in their forward positions, when the fric- Steering to either side is accomplished by means of the rear rudder planes 12, through hand wheel 14:. Altitude is governed by lever 18. When the machine is sufliciently clear of the ground, 37 is returned to its former position, allowing frames 66 and wheels 32 to resume the proper position for landing. In landing, the gyroscope is disconnected, and its brake applied,-- stopping its rotation; the propellers disconnected, and the check planes 8-9, are used as may be necessary by manipulation of lever 10.

What I claimas new, and desire to secure by Letters Patent is 1. In an aeroplane, the combination with a frame having fixed supporting surfaces and a balancing plane transversely pivoted at each side, of means for inclining said planes during the lateral displacements thereof by transmitting to saidplanes the momentum of a moving frame, comprising a gyroscope having a'vertical shaft mounted on a spherical or universally oscillab'le bearing, means cooperating with said shaft by which the inertia of the gyroscope cooperatwith the laterally tipping frame,

ing a pivoted and slotted member engaging said shaft and moved thereby during lateral :osc'il-lations thereof only, tension connect ons between said member and the balanc mg planes, and means to rotate the gyroscope.

-2. In an aeroplane, a motor, a frame,

\ allowing rotary and slotted and pivoted horizontal balancing planes pivoted trans- I versely on each .side, a gyroscope wheel, a vertical shaft therefor having a bearing oscillatory movement thereof, horizontally pivoted rock levers mounted on opposite sides of the machine with axes transverse to the balancing plane axes and having four arms or connectionactuating points disposed in quadrants of a circle about their axes, one arm disposed above said horizontal axis, one arm disposed belowsame, one arm extending horizontally inward toward center of machine, one arm extending outward from center of machine, connections between each of said upper arms and the gyroscope, connections between. each of said inner arms and the rear side of the balancing planes, connections between said outer arms and front side of the balancing planes, connections between the lower arms on opposite sides of machine, and means for giving the gyroscope a plurality of'revolutions to one of motor.

3. In an aeroplane, the combination with a frame-having fixed supporting surfaces and transversely Lpivoted' balancing planes arranged to be inclined by the lateral tipping momentum of the frame transmitted thereto, of a gyroscope mounted on said frame and having a vertical shaft, a-spherical bearing therefor, means to rotate the gyroscope, a. longitudinally-pivoted and slotted member moved by said shaft, and tension connections between said pivoted member and the balancing planes.

4. In an aeroplane, the combination with a frame having fixed supporting surfaces and lateral balancing planes pivoted trans-' versely at ,each side thereof and adapted and arranged to be moved by the lateral tipping momentum of the frame transmitted thereto'by suitable connections, of a gyroscope mounted on a vertical shaft having a spherical bearing and'cooperating to move the balancing planes, a longitudinallyslotted and pivoted member cooperating. 'with the gyroscope shaft,

tension connections between the slotted member and the balancing planes,

scope, and apositioning brake therefor.

5. In an aeroplane, the combination with supporting surfaces a frame having fixed transversely pivoted and. a balancing plane at each side, ofa gyroscope mounted on' a vertical shaft having a spherical bearing near its upper end andcausing said shaft.

to operate as a lever during the lateral .tipping movements of the frame, tension con nections between the planes andthe gyroscope shaft including v a longitudinally member engaging said shaft and inoperative during the-longitu-' dinal ,oscillations'thereofiand means to ro-.

tate the gyroscope.

1 6. .In an aeroplane, a framehaving fixed to: one at each side,

means .to rotate the gyro motor therefor.

supporting surfaces,- balancing planes 'located one on each side of same, a gyroscope wheel mounted on a vertical shaft having a spherical bearing-member fixed to and concentric with said shaft, a supporting body inclosing said shaft bearing and se arable on a line transverse to the axis of sai shaft, an annular gear revolubly mounted in said body and concentric with said shaft, connections between said shaft and annular gear for rotating same, connections between the balancing planes and gyroscope, and a motor operatively connected thereto. 1 I

7 In an aeroplane, a frame, balancing planes located on each side thereof, agyro-. scope cooperating to move said planes simultaneously in opposite directions, tension connections between same and gyroscope, and a manually actuated member cooperating to frictionally engage the gyroscope rim and initially position thesame normally with the frame.

8. In an aerial vessel, steering and propelling mechanism, balancing planes mounted on each side thereof, a gyroscope having a shaft mounted on a universal bearing, a disconnecting clutchtherefor, mechanism for initially positioning said gyroscope and tension connections between said planes and gyroscope, and means for actuating the positioning member.

9. In an aeroplane, a frame having fixed supporting surfaces, transversely-pivoted balancing planes located one on each side of said frame, a vertical shaft spherical bearing,

supporting means,

revolubly mounted on a a pivoted frame inclosing said shaft and slotted to allow free longitu- I dinal oscillation thereof, and tension connec-- tions between said slotted frame and the balancing planes.

10. In an aeroplane, the combination with a frame having fixed supporting surfaces, balancing planes pivoted transversely thereof a gyroscope mounted on the frame and having a vertical shaft, a spherical bearing for same, a longitudinallypivoted and slotted member engaging said shaft and allowing free oscillation of the shaft in said slot .without moving the same, connections between said slottedniember and the balancing planes, and means to rotate the-gyroscope.- y y 11. Combmation in an aeroplane, of a: frame, a plurality of concavo-convex supporting surfaces located ,'side by side, hori-' zontal transverse balancing planes, and

'means for actuating same comprising a roscope mounted on avertical haft, and a 12. In an. aeroplane; the combination with a frame having lateral win frame located at each side at the front, 7 ed sli Pp surfaces thereon, a vertical rudder for gova gyroscope wheel having 6 erning horizontal -movements, verti lsteer- 13g swinging said planes about their pivots, said actuating means comprising an automatically-locked friction device.

13. In an aeroplane, movable balancing planes located on each side of the machine, a gyroscope wheel, a vertical shaft therefor having a bearing allowing both rotary and oscillatory movements thereof, a brake or clamp. for holding the gyroscopewheel stationary at times, connections between the gyroscope shaft and balancing planes, and means for rotating gyroscope.

14. In an aeroplane, a lever locking device comprising a sector plate, having a-stud mounted perpendicularly thereon, a slideway or slot in said plate concentric with said stud, a double-arm lever pivoted'on said stud one arm having a shoe or projection adapted to slide in said slot, oppositely working spring-pressed locking rollers cooperatin to. lock said shoe in slideway, b

a second lever plvoted on sald stud, and means for unlockmg the rollers andmoving the double-arm lever.

.15. In an aeroplane, the combination with a mam frame havlng fixed supporting surfaces, a balancing plane transversely pivoted at each side thereof, connections loctween the planes including rocklevers for giving simultaneous opposite inclinations to said planes, .tension connections operating to give tosaid, planes their positive or lifting inclinations, of means for transmitting to said positive connections the force or momentum of said main frame during its lateral tipping movements comprising a vertical direct-acting laterally-inclinable lever or rotary shaft, a spherical bearing located near the upper end'of said shaft, a

gyroscope wheel mounted on the lower end of said shaft, and means to rotatethe gyroscope; saidpositive connections being connected with said shaft through a longitudi- Bally-slotted: and pivoted member engaging the same. T 16. Combination steering and propelling mechanism, an aerial brake, transversely pivoted balancing planes, a gyroscope for,

actuating. same, tension connection between gyroscope and balancing lanes, a gyroscope positioning brake, and means for giving the gyroscope a plurality of revolutions to oneof motor. 7

17.'In an aeroplane, a fram'e,-horizontal balancing planes pivoted transversely of frame, a gyroscope mounted on a vertical shaft, a plurality offriction or positioning brake arms therefor disposed so, as to engage the periphery arms,, mean s for moving. said connections of duplex, balanced, opposed and i clination said shaft, an

'sion connections ber and balancing planes, andmeansto' rosupporting I "versely-pivoted balancing planes located one in an aeroplane, of aof the gyroscope at times, connections-for actuating said brake equally and simultaneously to engage stop and hold the gyroscope stationary, connections between the gyroscope and balancing planes; and a motor therefor.

18. In an aeroplane, the combination with a' frame having fixed supporting surfaces and transverse balancing .planes pivoted thereto at each-side,-of a gyroscope mounted.

on said frame and having a vertical shaft,

a spherical bearing therefor, a longitudinally slotted member pivoted to the machine frame and engaging the gyroscope shaft,-

. and tension connections between said slotted member and the'balancing planes including rocklevers for changing the directlon of the.

line of motion of said connections.

' 19. Inan aeroplane, a frame, supporting surfaces therefor, horizontal balancing planes pivoted at each side of the center thereof, a .gyroscope, a vertical shaft therefor, a spherical bearing on said shaft, a laterally movable member encirclingsaid shaft and slotted in the line of forward motion of the machine and adapted to be moved by the lateral slotted member operatingto give the said planes a positive inclination, connections between the balancing planes operating' to give simultaneously to one a negative inwhen a positive inclination is given to-the other and vice versa, and means for rotating the gyroscope.

20. In an aeroplane, balancing mechanism comprising movable planes pivoted on each side of centerof the frame, a. gyroscope wheel mounted on a vertical revolubleshaft,

a bearing allowing oscillation therein of toand slotted longitudinally of machine, to allow of longitudinal oscillations of said shaft without moving the slotted frame,-tenbetween the slotted mem:

tate the gyroscope.

21; In an'aeroplane,

surfaces, horizontal on each side of. said frame, a. gyroscope mounted on a vertical shaft. having a spherical bearing, said shaft extending through said bearing, causing the upper end of. same to oscillate in an oppositedirection to that towardwhich the frame tips, a longitu'dinall. slotted memherpivoted to the frame. an adapted to be moved by said oscillation only pf said shaft, tension connections from said oscillatory member pivoted '110 a framehaving fixed. a

trans shaft during lateral oscillat ons only of the same, tension connections between said member and, the balan'clng planes, and means to rotate the gyroscope.

22. In an aero lane,

means for posltively inclining z Q89 a frame having fixed S pp rting sur aces, a hor1z'ontal trans-' verse balancing plane pivoted, at each. sidebetween said member and the balancing planes; the lateral tippingmovements of i the frame, through the cooperation of the gyroscope, causing a pull upon or a repositioning of said connections to positively incline one of said planes, and, through connections between the planes, a reverse or negative inclination to the opposite plane and vice-versa- 23. In an aeroplane, the combination with a main frame having fixed supporting surfaces, a balancing splane transversely pivoted at each side thereof, tension connections between said planes arranged to give .to the one a negative inclination whena positive inclination is given to the other, of means for positively inclining said planes, comprising a directly-connected Y gyroscope, a vertical shaft therefor having a spherical bearing therefor located near its upper end, a roscope wheel mounted on the 'lowerendo said shaft, a longitudinally slotted and pivoted member engaging said shaft, tension connections between said slotted member and the planes, and means to retate the gyroscope. v

24. In an aeroplane, a sector plate provided with a slideway, a pivot stud thereon, a double-arm lever mounted thereon provided with a shoe engaging in said slideway and having a double, incline extending each way from the center, flanged rollers engaging said inclined seats, spring pressed members for seating said rollers, and means located between said rollers and movable toward either end of the slide-way for unlocking rollers and moving said double-arm ever.

25. an organized aerial vessel, a fric-.

tionally locked manually-actuated plane moving mechanism, comprising a base plate having therein a slidewa e'qui-distant or parallel sies, a bi-directionally-movable plane-moving member registering in said slot and having formed thereon a shoe or slide adapted to move in said slot and having oppositely inclined locking. seats sloping downwardly each way from the center thereof, oppositely acting springpressed locking members carried by said shoe and registering with said inclined seats,

'andmanually actuated means operating between said locking members to simultaneously vunlock same and move the plane-moving-member. V ,7 26, an aeroplane, asector plate proor slot havingvidedwith a pivot stud, a slideway concentric therewith, a double-arm lever mounted on said stud and provided with a shoe movable in said slideway and having an incline sloping each way from the center thereof, a locking roller operating on each incline,

a spring-pressed plunger holding each roller,

against" its respective incline, pressure springs for said plungers, and manually actuated means for unlocking said rollers located between same.

27. In an aeroplane, a sector plate, a stud mounted on one edge of same perpendicular thereto, a circular slideway in said sector plate concentric with said stud, a-lever having oppositely disposed arms arranged and adapted to engage with and transmit rectilinear motion to plane-moving connections, a shoe on'one of said arms moving in said slideway, spring-pressed plungers located in each ,end of same, locking-rollers mounted in said slideway, and means for simultaneously unlockin the locking-rollers and moving the doub e-arm lever.

28. In an organized aeroplane, a frictionally locked bi-directionally movable planecontrolling device comprising a baseplate mounted on the machine frame and having a parallel-sided slideway or slot therein for the reception of the locking devices, a bi-directionally movable plane-controlling member movably mounted and registering with said slot, spring-pressed locking members carried by said plane-moving member and operating in opposite directions in said slot to lock said movable member, and manually actuated means for simultaneously un- I locking the locking devices and moving the plane-controlling member.

29. In an organized aeroplane having a frame, supporting surface, steering, balancing, propelling, and landing mechanism, a bi-directlonally movable plane-moving member, means for frictionally locking same against said bi directional movements, and manually actuated means for simultaneously unlocking and moving same in either of said bi-directional movements.

30. In an aeroplane, a lateral balancing mechanism comprising horizontal transversely-pivoted balancing planes located one at eachside of the machine, means for positively inclining said, planes comprising a directly-acting gyroscope shaft hung. on a universal joint or hearing and allowmg oscillation thereof "and function-ing as a vertical automatic oscillableplane-moving lever, connections between the gyroscope and balancing planes comprismg tension wires and a laterally-movable longitudinally-slotted member arranged to be moved by the lateral" oscillations only of the vertical lever, tenoperating to give to the one anegative inclination when a positive inclination is 'sion connecting-wires between the planes given to the other by the vertical lever, and

vice-versa', and means to rotate the gyroscope.

31. A leverage system for controlling the lateral balance of an aeroplane, by which the momentum or force generated by the lateral tipping movements of the frame is utilized to incline the balancing planes pivoted ateach side thereof transversely, through tension connections and rocklevers operating to change the direction of the line of motion of said connections, by combi nation therewith a gyroscope having a vertical shaft, a spherical bearing therefor allowing lateral oscillation thereof, a longitudinally-slotted member pivoted to the machine frame engaging said shaft and adapted to be laterally swung thereby to move the plane connections and allowing independent vertieal steering without interfering with the function of the gyroscope for automatic lateral balancing, and means to rotate the gyroscope.

In testimony whereof, I have signd my name to this specification in the presence of two subscribing witnesses, this twenty-third day of August 1909.

HERBERT E. HAWVES.

\Vitnesses V. E. MoUN'rroRT, C. L. LAznLLE. 

